An indoor gardening appliance includes a liner defining a grow chamber and a grow module rotatably mounted within the grow chamber and defining a root chamber. A hydration system is fluidly coupled to the root chamber for selectively implementing a hydration cycle where the root chamber is charged with mist and an air circulation system selectively urges a flow of air through the root chamber to maintain a desired temperature. A controller is configured for stopping the flow of air during the hydration cycle, e.g., to minimize disruption of the hydration cycle. The stopping of the flow of air may be time-based, e.g., based on the start/end times of the hydration cycle, or may be based on moisture level, e.g., as measured by an optical sensor.

An open-top gutter for cultivation of plants. In an example, the open-top gutter comprises at least one water space formed by a double edge and being closed at the top, or almost closed. The water space is open at the bottom of the gutter. In an example, the open-top gutter includes at least one separate water space formed by a partially double bottom and connected to the bottom of the gutter via a bottom gap. In an example, the open-top gutter includes a space limited by two side walls and a bottom wall and divided into trough-like compartments by at least one dividing wall. The dividing wall includes at least one water space formed by a double wall, open at the bottom of the gutter.

A container unit for hydroponics includes a container having an overflow unit and an outflow unit located therein. The overflow unit includes an overflow tube, and the outflow unit includes a siphon pipe which is height adjustable. A cover is mounted to the container and includes an opening, a first hole and a second hole. A pot is engaged with the opening of the cover. Two hooks are connected to the back of the container so as to be hooked to a shelve to form multiple rows of the containers between which the overflow tubes and the outflow tubes are connected via the first and second holes of the containers. The overflow tube and siphon pipe control the water level in the container to prevent plant root from being rotted.

The present disclosure relates to an apparatus for cultivating plants, the apparatus includes a cabinet having a cultivation space; a door opening and closing the cultivation space; a cultivation shelf disposed inside the cultivation space and on which a seed package containing plants for cultivation is seated; a lighting device for radiating light to the cultivation shelf; a water tank provided inside the cultivation space and storing water; and a water supply pipe supplying water from the water tank to the cultivation shelf.

The disclosed technology includes hydroponics systems and methods of efficient, configurable nutrient solution grow reservoirs that utilize shared components while creating more space in grow facilities. The hydroponics systems include vertical and horizontal rows or layouts of connected reservoirs that may include movable reservoirs to allow for better user access and reduce aisles, which allows space for more reservoirs in a grow facility. Multiple reservoirs may be connected to one another by irrigation tubing (e.g., as shown in in vertical layouts) or by pipes or irrigation tubing (e.g., as shown in horizontal layouts) and share various multiple system components, such as water pumps, water chillers, air pumps, float valves, and drain out systems. In some implementations, incorporation of the 4″ pipes in the horizontal layouts provides for efficient water circulation in a closed loop configuration throughout the disclosed hydroponic systems.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module rotatably mounted within the grow chamber and defining a root chamber. A hydration system is fluidly coupled to the root chamber for selectively implementing a hydration cycle where the root chamber is charged with mist and an air circulation system selectively urges a flow of air through the root chamber to maintain a desired temperature. A controller is configured for stopping the flow of air during the hydration cycle, e.g., to minimize disruption of the hydration cycle. The stopping of the flow of air may be time-based, e.g., based on the start/end times of the hydration cycle, or may be based on moisture level, e.g., as measured by an optical sensor.

Hydroponics systems and methods of efficient, configurable nutrient solution grow reservoirs include shared components while creating more space in grow facilities. The hydroponics systems include vertical and horizontal rows or layouts of connected reservoirs that may include movable reservoirs to allow for better user access and reduce aisles, which allows space for more reservoirs in a grow facility. Multiple reservoirs may be connected to one another by irrigation tubing (e.g., as shown in in vertical layouts) or by pipes or irrigation tubing (e.g., as shown in horizontal layouts) and share various multiple system components, such as water pumps, water chillers, air pumps, float valves, and drain out systems. In some implementations, incorporation of the 4″ pipes in the horizontal layouts provides for efficient water circulation in a closed loop configuration throughout the disclosed hydroponic systems.

An above ground watering system for vandaceous orchid air plants. Some embodiments may comprise one or more watering elements, such as a watering manifold that may deliver water through one or more outtake ports through water delivery members that may extend from the watering manifold and ribbons wrapped around the roots of the vandaceous orchid to deliver water and/or nutrients continuously via capillary action.

A system for automated plant condition notification, detection, and watering to improve plant growth and maintenance including a computing unit, an optical sensor, a soil moisture sensor, a water tank level sensor, a pump, and a computing unit. The computing unit includes a memory and a processor that receives a first input indicative of a user identifier and a communication type, a second input indicative of a plant type, a soil moisture input, a water level input, and an optical sensor input. The processor also determines a water pump initiation threshold and a water pump completion threshold based on one or more of the plant type, the optical sensor input, or the soil moisture input and determines a plant maturity optical value based on the plant type. Additionally, the processor transmits a water pump initiation, a water pump completion signal, and a notification via a selected communication method.

An indoor gardening appliance includes a grow module that is rotatably mounted within a grow chamber and that defines pod apertures for receiving a plurality of plant pods. A hydration system includes a discharge nozzle positioned within the grow chamber for selectively discharging a mist of nutrients. An electrostatic charging assembly is coupled to the discharge nozzle for selectively charging the mist of nutrients. By contrast, the plant pods may be electrically coupled to a grounding assembly for selectively grounding the root end of the plant pods. In this manner, the roots of the plants may have an opposing charge relative to the mist of nutrients such that the mist of nutrients are attracted to and deposited on the roots of plants.